‘Eavesdropping’ on Groupers’ Mating Calls Key to Survival

Researchers from FAU’s College of Engineering and Computer Science, FAU’s Harbor Branch Develop New Way to Identify Groupers by Their Sounds

Eavesdropping on groupers mating in their natural habitats isn’t creepy. In fact, it’s imperative to ensuring their survival. For years, scientists have used passive acoustic monitoring techniques to study the behavior of fishes. A particular application of this technique is used to observe the reproductive cycle of fishes, including groupers.

Results of the study, published in the Journal of the Acoustical Society of America, show that with this new approach, the researchers achieved vocalization classification accuracy of about 90 percent for four species of groupers – red hind (E. guttatus), Nassau grouper (E. striatus), yellowfin (M. venenosa), and black grouper (M. bonaci). This novel technique significantly outperformed previously reported methods for automatic classification of grouper calls.

Numerous fish produce sounds for many reasons like courtship and mating, navigation, and defending their territories from intruders. Some groupers produce sounds associated with courtship during spawning aggregation that are specific to species. They swim long distances and gather in high densities for mass spawning at precise locations and times. This widespread reproductive strategy is typically shared among the groupers.

“The sounds groupers make vary in the 10 to 500 Hertz frequency range and have distinctive characteristics that can be seen in a spectrogram, which is a visual representation of the spectrum of frequencies in a sound or other signal,” said Hanqi Zhang, Ph.D., lead author, associate chair, and a professor in the Department of Computer and Electrical Engineering and Computer Science at FAU. “For example, the red hind grouper calls are in the 100 to 200 Hertz band, while the Nassau grouper calls are in the 30 to 300 Hertz band.”

In earlier work, the FAU researchers developed an automated classification algorithm, FADAR (Fish Acoustic Detection Algorithm Research), capable of identifying four species of grouper in their natural environment with a classification accuracy of about 82 percent. FADAR consists mainly of three stages: signal de-noising, feature extraction, and classification. Although FADAR provides an automated approach to vocal classifications, this machine learning approach still relies heavily on a carefully designed processing and feature extraction method.

The new deep learning-based detectors and classifiers developed by the FAU researchers don’t require sophisticated preprocessing and hand-crafted feature extraction procedures.

For the study, Zhuang, and co-authors Ali K. Ibrahim, a graduate student at FAU; Laurent M. Cherubin, Ph.D., an associate research professor at FAU’s Harbor Branch; Michelle T. Scharer-Umpierre, Ph.D., an associated researcher at the University of Puerto Rico; and Nurgun Erdol, Ph.D., chair and professor in FAU’s Department of Computer and Electrical Engineering and Computer Science, tested convolutional neural networks and long short-term memory networks to classify the sounds produced by the four species of groupers. They were able to demonstrate that a data-driven feature extractor like the one they used in their study outperformed the hand-crafted one with a large margin.

The concentrated nature and short duration of the grouper spawning season – a couple of months each year – make them especially vulnerable to overfishing. Furthermore, it typically takes them five to 10 years to reach sexual maturity before they can reproduce and replenish their populations.

“It is reported that about 12 percent of the 163 grouper species worldwide are at risk of extinction if current overfishing trends continue, and an additional 13 percent are Near Threatened,” said Stella Batalama, Ph.D., dean of FAU’s College of Engineering and Computer Science. “Our marine resources are not infinite, and studying the spawning aggregations of groupers and other species is vital to conservation efforts aimed at reversing worldwide depletion of endangered fishes and sustaining marine biodiversity. The technology developed by our researchers is a critical tool to help accomplish this important endeavor.”

Findings from this study also will help to inform fisheries managers where protective measures are necessary. Future studies will implement the new algorithm developed by the researchers in a real-time platform and will explore the potential of applying this method to detect and classify other fish calls.

This research is supported by the Harbor Branch Oceanographic Institute Foundation, and in part, by NOAA Saltonstall-Kennedy Grant (No. NA15NMF4270329).